Fiber optic networks having a self-supporting optical terminal and methods of installing the optical terminal

ABSTRACT

Fiber optic networks having a self-supporting optical terminal along with methods of installing the optical terminal are disclosed. The fiber optic network comprises an optical terminal having a housing and a tether cable attached to the housing. The tether cable is aerially supported by the tether cable of the optical terminal using a cable clamp. The fiber optic networks can aerially deploy the self-supporting optical terminal without the use of a support strand and lashing like conventional optical terminals since the optical terminal is light-weight and has a small form-factor. The tether cable may be attached to one or more mounting features of the housing and the cable clamp grips a portion of the tether cable for the aerial installation.

RELATED APPLICATIONS

This application claims the benefit of priority under 35 U.S.C. § 119 of U.S. Provisional Application Ser. No. 62/935,245 filed on Nov. 14, 2019, the content of which is relied upon and incorporated herein by reference in its entirety.

BACKGROUND

The disclosure is directed to fiber optic networks having a self-supporting optical terminal and methods of installing the self-supporting optical terminal that improve network deployment and efficiency. More specifically, the disclosure is directed to fiber optic networks having a small-form factor optical terminal that does not require a support strand and lashing wire for aerial deployments, but instead is aerially supported using an input tether cable along with methods for installing the optical terminal,

Optical fiber is increasingly being used for a variety of applications, including but not limited to broadband voice, video, and data transmission. As bandwidth demands increase optical fiber is migrating toward subscribers in outdoor communication networks such as in fiber to the premises applications such as FTTx, 5G deployments and the like. To address this need for making optical connections in communication networks for outdoor environments hardened fiber optic connectors were developed. As used herein, the term “hardened” describes a connector or port intended for making an environmentally sealed optical connection suitable for outdoor use, and the term “non-hardened” describes a connector or receptacle port that is not intended for making an environmentally sealed optical connection such as the well-known SC connector.

Network operators face many challenges for building, deploying and connecting fiber optic connections in the outside plant communication network such as in an aerial deployment. For instance, conventional terminals or closures are typically mounted on poles or supported aerially using an additional support strand (e.g., separate support wire spanning between poles with the terminal or closure attached to the support wire) due to the size and weight of the terminal or closure. The aerial installation of the conventional terminals or closures must also be robust enough to withstand additional loading beyond its own weight loading such as handling dynamic wind loads that may induce galloping, ice loading which can contribute significantly to the weight and wind loading and the like. Consequently, fiber optic networks comprising the aerially mounted terminals or closures must handle extreme conditions for providing robust performance in the outside plant aerial environment.

Network operators may have right of way issues for installing outside plant deployments as well. For instance, a network operator may not own the poles needed for an aerial deployment and may be required to make a payment to use space on the poles for mounting terminals or closures. Besides right of way issues for the equipment, network operators may have limited space to available on existing poles for mounting terminals or closures due to congestion from utilities or other communication networks. Likewise, buried installations may have limited space availability in an existing vaults or pedestal for mounting terminals or closures or managing slack storage. In other words, deploying the terminal or closures along with the slack storage for the fiber optic cables may consume limited and valuable space or become unsightly in aerial deployments. For these reasons, the prior art fiber optic networks can have unorganized or unsightly deployments that may also take up large amounts of space in aerial or buried deployments and that may also require payments by the network operator.

Consequently, there exists an unresolved need for fiber optic assemblies in fiber optic networks that may be deployed in a space-saving manner while still allowing quick and easy deployment along with being aesthetically pleasing.

SUMMARY

The disclosure is directed to fiber optic networks having at least one optical terminal and a cable clamp for aerially supporting the optical terminal. Also disclosed are fiber optic networks comprising an optical terminal comprising cable slack storage arrangements. The concepts disclosed provide an improved deployment of optical terminals in fiber optic networks.

One aspect of the disclosure is directed to a fiber optic network comprising at least one optical terminal and a cable clamp for aerially supporting the optical terminal without using a separate support strand. The optical terminal comprises a housing, at least one tether cable attached to the housing, and a linear array of connection ports disposed on the optical terminal. The cable clamp is attached to a structure at a first end and grips a portion of the at least one tether cable at the second end so that the optical terminal is aerially supported by the at least one tether cable.

Another aspect of the disclosure is directed to a fiber optic network comprising at least one optical terminal and a cable clamp for aerially supporting the optical terminal without using a separate support strand. The optical terminal comprises a housing comprising one or more mounting features, at least one tether cable attached to the housing of the optical terminal where a portion of the tether cable is attached to the one or more mounting features, and a linear array of connection ports disposed on the optical terminal. The cable clamp is attached to a structure at a first end and grips a portion of the at least one tether cable at the second end so that the optical terminal is aerially supported by the at least one tether cable.

Yet another aspect of the disclosure is directed to fiber optic network comprising an optical terminal having a cable slack storage arrangement. The optical terminal comprises a housing having one or more mounting features disposed on an outer perimeter and a linear array of connection ports. The connection ports are suitable for making an optical connection with the optical terminal and define a connection plane aligned on respective centerlines of the linear array of connection ports, and the plurality of mounting features are at least partially disposed on the connection plane. At least one tether cable is attached to the housing of the optical terminal, and a portion of the tether cable is wrapped about the outer perimeter of the housing in one or more coils and secured to the housing using one or more of the plurality of mounting features.

A further aspect of the disclosure is directed to a method of installing an optical terminal in a fiber optic network. The method comprises: providing an optical terminal comprising a housing and at least one tether cable attached to the housing, where the housing comprises at least one mounting feature; attaching a cable clamp to a structure; securing a portion of the tether cable in the cable clamp; and attaching a portion of the tether cable to at least one mounting feature of the housing so that the optical terminal is aerially supported by the at least one tether cable.

Additional features and advantages will be set forth in the detailed description which follows, and in part will be readily apparent to those skilled in the art from that description or recognized by practicing the same as described herein, including the detailed description that follows, the claims, as well as the appended drawings.

It is to be understood that both the foregoing general description and the following detailed description present embodiments that are intended to provide an overview or framework for understanding the nature and character of the claims. The accompanying drawings are included to provide a further understanding of the disclosure and are incorporated into and constitute a part of this specification. The drawings illustrate various embodiments and together with the description serve to explain the principles and operation.

BRIEF DESCRIPTION OF THE FIGURES

FIG. 1 is a perspective view of an explanatory optical terminal for a fiber optic network according to the disclosure;

FIG. 2 depicts a portion of a fiber optic network comprising the optical terminal in an aerial deployment that is supported by the tether cable of the optical terminal according to the disclosure;

FIG. 3 shows a schematic representation of the fiber optic network having the optical terminal supported by its tether cable using a cable clamp;

FIG. 4 shows a top down schematic view of a portion of FIG. 3 showing the housing of the optical terminal attached to its tether cable using cable ties through the mounting features of the housing according to the disclosure;

FIG. 5 is a perspective view of the optical terminal with a plurality of cable assemblies having their respective fiber optic connectors received in respective connection ports of the optical terminal;

FIG. 6 is a plan view of an optical terminal having a cable slack storage arrangement using one or more mounting features of the housing;

FIG. 7 is a perspective view of another optical terminal that may use the aerial installation or cable slack storage arrangement disclosed herein; and

FIG. 8 is a partially exploded view of a cable assembly of FIG. 5.

DETAILED DESCRIPTION

Reference will now be made in detail to the embodiments of the disclosure, examples of which are illustrated in the accompanying drawings. Whenever possible, like reference numbers will be used to refer to like components or parts.

The concepts disclosed advantageously provide fiber optic networks comprising a self-supporting optical terminal comprising a housing and a tether cable that is attached to the housing. Unlike conventional optical terminals that require lashing to support strand for aerial support, the optical terminal disclosed is aerially supported by its own tether cable using a cable clamp. Consequently, the network operator may deploy the optical terminal into a fiber optic network in a quick and efficient manner without the use of a separate strand wire for aerial support. Further, network operators may aerially deploy optical terminals without mounting the optical terminal directly to a pole. Thus, the network operator can save the time and expense when installing the optical terminal in an aerial application. Moreover, the network operator can avoid paying fees for mounting equipment to pole that they may not own and also avoid congestion of equipment on poles. The fiber optic networks disclosed are explained and depicted with reference to an explanatory optical terminal, but other suitable types of terminals or closures may use the concepts disclosed herein.

FIG. 1 shows an optical terminal 200 that may be used as a portion of a fiber optic network 1000 as depicted in FIGS. 2-4. Optical terminal 200 comprises a housing 210 and at least one tether cable 270 attached to the housing 210 of the terminal 200. The tether cable 270 may be permanently attached to the optical terminal 200 or it may have a fiber optic connector terminated on its end so that the tether cable 270 may be removed and replaced from the optical terminal if damaged. The optical terminal 200 also comprises one or more linear arrays of connection ports 236 disposed on the optical terminal 200. Connection ports 236 are suitable for making an optical connection with the optical terminal. For instance, each connection port 236 may receive a suitable fiber optic connector 10 that is terminated to an end of the fiber optic cable 90 to form the cable assembly 100 such as shown in FIG. 5. For explanatory purposes, the optical terminal 200 depicted in FIG. 1 has a single linear array of connection ports 236, but other optical terminals may have more than one linear array of connection ports 236 such as shown in FIG. 7 and use the concepts disclosed herein. Further details of an explanatory optical terminal 200 (e.g., multiport) are disclosed in PCT publication WO2019/005203, which is incorporated herein by reference.

The optical terminal 200 also comprises one or more mounting features 210MF. Mounting features 210MF are disposed on opposite sides of the housing 210. More specifically, mounting features 210MF may be disposed on both the left and right outboard sides and each side may have one or more mounting features as desired. The mounting features 210MR are shown as slots that are suitable for receiving cable ties 3 or the like, but other configurations are possible. In this embodiment, the housing 210 comprises a rectangular box form-factor and the mounting features 210MF are disposed on one or more long-sides (LS) of the rectangular box form-factor. For instance, each long side (LS) of the optical terminal 200 may have two mounting features 210MF such as depicted in FIGS. 1 and 5. Consequently, the optical terminal 200 may be attached from either side as desired and be secured at two locations for stability. However, the optical terminal may comprise one or more mounting features 210MF on other portions of the housing 210 such as the short side opposite the connection ports 236 or on the bottom or top if desired.

In this embodiment, optical terminal 200 may also comprise a plurality of actuators 310 associated with the linear array of connection ports 236. The actuators 310 are used for releasing a fiber optic connector that may be installed into the respective connection port 236. Actuators 310 may be buttons that translate to disengage a locking feature (not visible) of the connection port 236 to release the fiber optic connector. The connector ports 236 may also be configured such that the fiber optic connector is automatically secured to the optical terminal by fully seating the fiber optic connector in the connection port 236 if desired. However, optical terminal 200 may use any suitable structure for securing the fiber optic connector to the connection port 236 such as a threads, clips or other structure.

FIGS. 2-4 depict portions of a fiber optic network comprising an aerially supported optical terminal 200. As depicted in FIGS. 2 and 3, the optical terminal 200 is aerially supported by its own tether cable 270 without the need or expense of a separate support strand like conventional optical terminals. Instead, a first end of a cable clamp 1 is attached to a structure such as a pole or premises and a second end grips a portion of the tether cable 270 so that the optical terminal 200 is aerially supported by the tether cable 270. Consequently, the network operator does not need to deploy a separate support strand and lash the optical terminal 200 to the support strand like conventional installations. Conventional installations lash a cable to the support strand (e.g., wrap a filament about the cable and the support strand along the supported length) so that the cable is supported or carried by the strength of the support strand and not the cable over the span length as known to the skilled person. Nor does the network operator need to mount the optical terminal 200 directly to the pole or structure like other conventional installations.

As an alternative to the cable clamp 1, a hanger may be attached at a first end to a structure and used in a similar fashion for supporting the optical terminal 200 without gripping a portion of the tether cable 270. Instead, the second end of the hanger attaches directly to a portion of the optical terminal 200 such as the housing 210 for aerially supporting the optical terminal 200 without using a support strand. In this case, the housing 210 may have a dedicated attachment point or eyelet for the second end of the hanger.

The length that may be aerially spanned by the optical terminal in the fiber optic network disclosed herein will depend on the cable type used for the tether cable. For instance, a tether cable 270 may be a figure-8 design with a dedicated strength member in one of the lobes for spanning a longer length compared with a conventional flat cable design having smaller GRP strength members. Consequently, by varying the type of cable used for the tether cable different span lengths are possible.

Returning to FIG. 2, the tether cable 270 of the optical terminal 200 may be attached to one or more mounting features 210MF such as shown in FIG. 2. As depicted, the tether cable 270 is attached to the one or more mounting features 210MF using one or more cable ties 3 or the like. The tether cable 270 may form a portion of a loop 270L before being attached to the mounting features 210MF of the optical terminal 200. As depicted, the optical terminal 200 may be orientated so that the connection ports 236 face the pole, thereby providing easier access to the connection ports 236 for the technician that may lean a ladder against the pole. Moreover, the optical terminal 200 may be able to slide on the tether cable 270 toward the pole if the cable ties 3 are not overly tightened, thereby allowing the technician to access the optical terminal 200 closer to the pole and complete their work and then slide the optical terminal 200 back to its desired position on the tether cable 270.

Additionally, the tether cable 270 may form a portion of the loop 270L before being gripped by the cable clamp 1 as depicted. In other words, the tether cable 270 extends away from the housing 210 and then loops back toward the housing 210. For instance, the tether cable 270 may loop back toward a long-side (LS) of the housing 210 that has a rectangular box form-factor. Further, loop 270L may comprise several coils if desired for managing tether cable slack as needed.

The other end of the tether cable 270 of the optical terminal 200 may be optically connected to a distribution cable in the fiber optic network 1000 as desired. For instance, the other end of the tether cable 270 may be terminated with a fiber optic connector or it may enter into another device like a closure for optical connection. Consequently, the optical terminal 200 is installed into the fiber optic network 100 without being aerially supported using a separate support strand like conventional optical terminals.

The relatively small rectangular box-shape for the optical terminal 200 provide installation advantages for the network operator. FIG. 4 shows that the rectangular box form-factor for the optical terminal 200 the advantage of aerially supporting the optical terminal 200 in a vertical manner as well for providing a relatively small footprint for shedding water, reducing ice loading or the like. In other words, aerially supporting the optical terminal in a vertical manner provides a small footprint for reducing the gathering ice during inclement weather, and thus greatly reducing the weight that must be supported during extreme conditions.

The optical terminals 200 disclosed comprise a relatively high-density of connection ports 236 along with an organized arrangement for connectors 10 attached to the optical terminals 200. Housing 210 have a given height H, width W and length L that define a volume for the multiport as depicted in FIG. 1. By way of example, housing 210 of multiport 200 may define a volume of 800 cubic centimeters or less, other embodiments of shells 210 may define the volume of 400 cubic centimeters or less, other embodiments of shells 210 may define the volume of 100 cubic centimeters or less as desired. Some embodiments of optical terminals 200 comprise a port width density of at least one connection port 236 per 20 millimeters of width W of the optical terminal 200. Other port width densities are possible such as at least one connection port per 15 millimeters of width W of the optical terminal 200. Likewise, embodiments of optical terminals 200 may comprise a given density per volume of the housing 210 as desired.

The concepts disclosed allow relatively small form-factors for optical terminals as shown in explanatory Table 1. Table 1 below compares representative dimensions, volumes, and normalized volume ratios with respect to the conventional optical terminals having adapters disposed in the housing for receiving OptiTap® connectors that are available from Corning Optical Communications of Charlotte, N.C. for 4, 8 and 12 ports as comparative examples for the compactness of the optical terminals disclosed in the present application. Specifically, Table 1 compares examples of the conventional prior art optical terminals with optical terminals having a linear array of ports as depicted in FIG. 1. As revealed by Table 1, the respective volumes of the conventional prior art optical terminals with the same port count are on the order of ten times larger than optical terminals like those shown in FIG. 1 with the same port count as disclosed herein. By way of example and not limitation, the optical terminal 200 may define a volume of 400 cubic centimeters or less for 12-ports, or even if double the size could define a volume of 800 cubic centimeters or less for 12-ports. Optical terminals with smaller port counts such as 4-ports could be even smaller such as the housing defining a volume of 200 cubic centimeters or less for 4-ports. Optical terminals with sizes that are different will have different volumes form the explanatory examples in Table 1 and these other variations are within the scope of the disclosure. Consequently, it is apparent the size (e.g., volume) of optical terminals of the present application are much smaller than the conventional prior art optical terminals. In addition to being significantly smaller, the optical terminals of the present application are also much lighter than the conventional prior art optical terminals. Of course, the examples of Table 1 are for comparison purposes and other sizes and variations of optical terminals may use the concepts disclosed herein as desired.

One of the reasons that the size of the optical terminals may be reduced in size with the concepts disclosed herein is that the fiber optic connectors that cooperate with the optical terminals may have locking features that are integrated into the housing 20 of the connectors 10. In other words, the locking features for securing fiber optic connector are integrally formed in the housing of the connector, instead of being a distinct and separate component like a coupling nut of a conventional hardened connector used with conventional optical terminals. Conventional connectors such as OptiTap connectors for conventional optical terminals have threaded connections that require finger access for connection and disconnecting. By eliminating the threaded coupling nut (which is a separate component that must rotate about the connector) the spacing between connection ports may be reduced. Also eliminating the dedicated coupling nut from the conventional connectors also allows the footprint of the connectors to be smaller, which also aids in reducing the size of the optical terminals disclosed herein.

TABLE 1 Comparison of Conventional Optical Terminals with Optical Terminal 200 Dimension Optical Port L × W × H Volume Normalized Terminal Type Count (mm) (cm³) Volume Ratio Conventional 4 274 × 66 × 73 1320 1.0 8 312 × 76 × 86 2039 1.0 12  381 × 101 × 147 5657 1.0 Optical Terminal 4  76 × 59 × 30 134 0.10 200 8 123 × 109 × 30 402 0.20 12 159 × 159 × 30 758 0.14

As shown in FIG. 5, one or more fiber optic connectors 10 on the respective terminated ends of the cable assemblies 100 may be attached to respective ports 236 of the optical terminal 200 to form a portion of the fiber optic network 1000. Cable assemblies 100 comprises a fiber optic connector 10 terminated on an end of a fiber optic cable 90. The cable assemblies 100 are used for routing optical fibers closer to subscribers as known in the art. Optical terminal 200 may have any suitable number of connection ports 236 for receiving the fiber optic connectors 10 of respective cable assemblies 100. The connection ports 236 may be arranged as one or more linear arrays of connection ports 236 on optical terminal 200. Each linear array of connection ports 236 disposed on the optical terminal 200 define a connection plane CP aligned on the centerlines of the connection ports 236 of the linear array such as shown in FIG. 1.

The optical terminals 200 disclosed herein may also have advantageous cable slack storage arrangements. FIG. 6 is a plan view of an optical terminal 200 having a cable slack storage arrangement using one or more mounting features 210MF of the housing 210. As depicted, housing 210 comprises a plurality of mounting features 210MF disposed on an outer perimeter along with a linear array of connection ports 236. The connection ports 236 define a connection plane (CP) aligned on the respective centerlines of the linear array of connection ports 236 (in the plane of the paper). The plurality of mounting features are at least partially disposed on this connection plane (CP). Consequently, the tether cable 270 attached to the housing 210 may have a portion of the tether cable 270 wrapped about the outer perimeter of the housing 210 in one or more coils and secured to the housing 210 using one or more of the plurality of mounting features 210MF. For instance, the tether cable 270 may be securing to the housing using cable ties or the like for a neat and organized cable slack storage in buried, aerial or other applications. FIG. 7 depicts another optical terminal 200 that has two linear rows of connection ports 236 that may also use the concepts disclosed herein.

FIG. 8 is a partially exploded view of a cable assembly 100 that terminates a representative fiber optic cable (hereinafter cable) 90 to a fiber optic connector 10. Further details of fiber optic connector 10 are disclosed in PCT publication WO2019/005197, which is incorporated herein by reference.

Cable 90 comprises at least one optical fiber 92 and a cable jacket 98 and may include other components or not. The cable 90 may comprises an asymmetrical cross-section having a major axis MAA and a minor axis MIA as shown in FIG. 8 or the cable may be a round cable if desired. As shown in FIG. 8, cable 90 may further comprises one or more strength members 94. The strength members 94 may be any suitable materials such as glass-reinforced rods, aramid yarns, fiberglass, metal wires or the like if used.

As shown, fiber optic connector 10 comprises a housing 20 and a ferrule 30. The housing 20 comprises a rear end 21 and a front end 23 with a longitudinal passageway 22 extending from the rear end 21 to the front end 23. The housing 20 also comprises a keying portion 20KP that may be disposed on an opposite side from a locking feature 20L or not as desired. Disposed on an opposite side means that the keying portion 20KP is about 180 degrees from the locking feature 20L in a rotational orientation about the housing 20, but other arrangements of the locking feature and keying portions are possible using the concepts disclosed herein. Ferrule 30 comprises a fiber bore 32 extending from a rear end 31 to a front end 33. The passageway 22 of housing 20 allows one or more optical fibers of cable 90 to pass through the housing 20 for insertion into fiber bore 32 of ferrule 30.

As depicted, the ferrule 30 may be a portion of a ferrule assembly 60 and the fiber optic connector 10 may also comprise a spring 38 for biasing the ferrule assembly 60 forward. The ferrule assembly 60 may comprise a ferrule holder 49 and ferrule 30. The ferrule assembly 60 may be inserted into housing 20 for assembly. Specifically, the assembly of the ferrule holder 49 and ferrule 30 are inserted into housing 20 from the front end 23 until they are retained by latch arms 20LA of housing 20. Latch arms 20LA may have ramp portions for aiding portions of ferrule holder 49 to deflect the latch arms 20LA outward as the ferrule holder 49 is inserted into housing 20 and then the latch arms 20LA spring back over ferrule holder 49 for retaining the same within the housing 20. However, other assemblies, orientations or constructions are possible for the fiber optic connector 10 according the concepts of the disclosure.

Fiber optic connector 10 may also comprise other components as desired. By way of example, fiber optic connector 10 may further comprise a cable adapter 59 that is received at a rear end 21 of housing 20 for receiving and securing cable 90. Cable adapter 59 allows different cables to be used with the housing 20. For instance, the cable adapter 59 may have an internal passageway sized and shaped for the desired cable. Other alternatives are possible for securing the cable such as using a crimp band or the like. Fiber optic connector 10 may also comprise a boot 70 that is disposed about a rear part of the connector for inhibiting sharp bending of the cable at the rear of the fiber optic connector 10.

Housings 20 of fiber optic connectors 10 may also have suitable features or structures for sealing connectors 10. The sealing plane should be located at a suitable location along the housing 20 for providing suitable environmental protection as necessary for the desired environment. Illustratively, housing 20 may include one or more grooves 20G for receiving an appropriately sized O-ring 65. Housings 20 may include other features or structures for aiding in sealing. For instance, the housing 20 may have a suitable surface for receiving a portion of a heat shrink 99 or the like for sealing between a portion of the cable 90 and the connector 10 when assembled. Any suitable heat shrink 99 may be used such as a glue-lined heat shrink. It is noted that the heat shrink 99 is depicted in its final form. Moreover, other structures or features are possible for aiding in providing a robustly sealed cable assembly 100.

Cable adapters 59 may comprise an aperture or a cable adapter key as desired. Generally speaking, cable adapter 59 comprises passageway from a cable adapter front end to a cable adapter rear end. Passageway allows the optical fiber 92 of cable 90 to pass therethrough. A shoulder (not numbered) allows cable adapter 59 to have a snug fit within the passageway 22 of housing 20 and inhibits adhesive from wicking or flowing forward of the shoulder. Any adhesive or epoxy used for securing cable adapter may wick around the recessed surface for creating a sufficient bonding area and any excessive adhesive or epoxy may flow into the aperture of cable adapter 59. Housings 20 may also include one or more apertures 29 for injecting epoxy or adhesive or the adhesive or epoxy may be placed on the cable adapter before insertion into the housing. For instance, housing may include two apertures 29 so that air may escape as adhesive or epoxy is injected. Additionally, the one or more apertures 29 may be aligned with the apertures of the cable adapter 59 so that the adhesive or epoxy also secures the strength members 94 of cable 90 to the cable adapter 59 that is secured to the housing 20, thereby forming a robust cable/connector attachment and also providing sealing at the rear end. The passageway of cable adapter 59 is sized and shaped for the particular cable 90 that is intended to be secured using the cable adapter along with the appropriate components as appropriate. The rear portion of the cable adapter 59 may comprise one or more ribs suitable for receiving a boot or overmold on the rear portion. The ribs may aid in the retention of the boot or overmold.

This embodiment also comprises a boot or overmold disposed on the rear portion of cable adapter 59 as shown. Further, when assembled a sealing element such a heat shrink 99 is disposed over the boot or overmold. The sealing element may also be disposed over a portion of the housing 20 as shown. Placing the sealing element over boot or overmold and a portion of the housing 20 allows for sealing of the cable jacket to the rear of the connector. This may also improve the bending strain-relief for the cable assembly.

Housing 20 comprises a part of the rear portion RP having a round cross-section RCS and a part of the front portion having a non-round cross-section NRCS. Housing 20 may have other features such as further comprising a transition region TR disposed between the rear portion RP and the front portion FP. The transition region TR may comprise an asymmetric portion AT. The transition region TR or asymmetric portion AT may have any suitable geometry or configuration as desired. In one embodiment, the transition region comprises a threaded portion TP. The threaded portion TP may be used for attaching a dust cap to the connector and/or for converting the footprint of the connector using other suitable components such as converting to an OptiTap® connector.

Housing 20 of fiber optic connector 10 comprises one or more features for alignment during mating and may also comprise other features for securing or locking the connector in a suitable connection port or device. Housing 20 may have a relatively compact form-factor such as having a length of about 40 millimeters (mm) or less and a cross-section dimension of about 15 mm or less such as 12 mm or less, but other suitable dimensions are possible for the housing. Due to the construction of housing 20, the optical terminal 200 may have the connection ports 236 arranged in a dense linear array since the connectors do not require a threaded component or bayonet for securing the connector in the port.

As used herein, the transition region TR is disposed between the rear end 21 and the front end 23 where the housing 20 makes a transformational shift in the primitive cross-sectional shapes from a part of a rear portion RP to a part of the front portion FP. As used herein, a primitive cross-section means the outer perimeter of the cross-section without regard for the internal features of the cross-section. Further, portions of the cross-sections may include other features that modify the shape of the primitive cross-sections as desired such as a keying feature, retention feature or a locking feature, while still practicing the concepts of the transition region TR or front/rear portions as disclosed herein. For instance, a front portion FP may have rounded corners or chamfered corners while still being a rectangular cross-section.

In this embodiment of housing 20, the front portion FP of housing 20 has a rectangular cross-section that provides a first orientation feature for the connectors for alignment during mating and inhibit insertion into a non-compliant device or port. The non-round cross-section NRCS has the rectangular cross-section. The rectangular cross-section provides the first orientation feature since the rectangular portion may only be inserted into a complimentary device or port in certain orientations due to its rectangular shape, thereby inhibiting incorrect insertion or insertion into non-compliant devices or ports.

The front portion FP of housing 20 depicted has more than one primitive cross-sectional shape over its length. Specifically, the front portion FP of housing 20 of also comprises another cross-section portion ACSP. By way of explanation, the another cross-sectional portion (ACSP) may comprise a SC footprint. The SC footprint can, in part, be similar to the inner housing of a conventional SC connector. This particular housing footprint is useful for allowing the connectors disclosed to be backwards compatible into existing devices or ports using well-established connector footprints as desired. Other embodiments may have fiber optic connectors configured for LC connector footprints or other known connector footprints as desired.

FIG. 8 shows the keying portion 20KP of housing 20 at the top, and on the opposite side (e.g., bottom and not visible) is the locking feature 20L of housing 20. The locking feature 20L may comprise a ramp 20R for cooperating and securing fiber optic connector 10 in the optical terminal 200. The locking feature 20L may comprise any suitable geometry for securing the connector 10 such a ramp 20R with a ledge 20LD such as shown in PCT publication WO2019/005197.

Rear portion RP may include one or more locking features that alter or modify the cross-section. For instance, housing 20 may also include locking feature 20L so that the connector may secured in an adapter, port or other suitable device. For instance, locking feature 20L may comprise features integrated into the housing such as one or more of a groove, a shoulder such as a ramp with a ledge. In these examples, the locking features 20L advantageously are integrated into the housing 20 and do not require extra components and may be used with any of the disclosed concepts. In some embodiments, the locking features 20L are subtractive portions from the primitive geometry of the rear portion RP such as a ramp or notch integrally formed in the round rear portion RP of housing 20. Consequently, having the locking features integrated into the housing 20 (e.g., monolithically formed as part of the housing) may allow denser arrays of connectors in complimentary devices. Moreover, these locking features integrated into the housing 20 are rearward of the sealing location. For example, the integrated locking features of housing 20 are disposed rearward of at least one groove 20G that seats O-ring 65. Locking feature 20L may cooperate with features of a complimentary mating device for securing the mating of the connector 10 with the complimentary mating device.

Housing 20 has features that aid in the proper alignment or orientation of the connector with the port such as markings, keys, keyways, etc. without changing the primitive form-factors of the housings that are disclosed and claimed herein. Additionally, housing may have other features for mating with a complimentary device. Thus, the features of housing 20 are used for aligning the fiber optic connector 10 within the port 236 of optical terminal 200.

Keying portion 20KP has a predetermined location with respect to an orientation of housing 20 for aligning the form-factor of the housing with a respective port on a mating device such as an optical terminal. For instance, the housing 20 or keying portion 20KP provides a proper orientation for connection in one orientation, which may be desired for connectors having angled ferrules. In this embodiment, keying portion 20KP ensures correct rotational orientation of the connector 10 during insertion into port 236 and mating with the optical terminal 200. In this embodiment, the fiber optic cable 100 is aligned to the keying feature 20K the major axis MAA of the fiber optic cable 90 is aligned in the respective port 236 of the optical terminal 200 so that the major axis of the cable 90 is perpendicular to the connection plane CP as depicted in FIG. 5. The connection plane CP is defined as passing thru the centerlines of the linear array of connection ports 236 as shown in the FIG. 1.

In this embodiment, the keying portion 20KP is configured as a female key or a subtractive portion on housing 20 such as a female keyway or a slice on the side of the connector leaving a D-shape. The keying portion 20KP extends into the transition region as shown. The keying portion 20KP cooperates with a suitable keying portion in a connection port 236 of the optical terminal 200 such as an additive or male portion for inhibiting non-compliant connectors from being inserted into the connection port. Although, the keying portion 20KP is disposed about 180 degrees from the at least one locking feature 20L, other arrangements are possible where the keying portion 20KP is disposed less than 180 degrees from the at least one locking feature 20L. In other embodiments, keying portion 20KP may be arranged as a subtractive portion that removes a side or slice of the housing 20 for creating a D-shaped cross-section over the length of the keying portion 20KP; instead of the female keyway shown. Moreover, other structures may be used for the keying portion 20KP such as a male key with the complementary structure on the optical terminal 200.

Although the disclosure has been illustrated and described herein with reference to explanatory embodiments and specific examples thereof, it will be readily apparent to those of ordinary skill in the art that other embodiments and examples can perform similar functions and/or achieve like results. All such equivalent embodiments and examples are within the spirit and scope of the disclosure and are intended to be covered by the appended claims. It will also be apparent to those skilled in the art that various modifications and variations can be made to the concepts disclosed without departing from the spirit and scope of the same. Thus, it is intended that the present application cover the modifications and variations provided they come within the scope of the appended claims and their equivalents. 

We claim:
 1. A fiber optic network, comprising: at least one optical terminal, comprising: a housing; at least one tether cable attached to the housing of the at least one optical terminal; and a linear array of connection ports disposed on the optical terminal; and a cable clamp for aerially supporting the at least one optical terminal, the cable clamp is attached to a structure and grips a portion of the at least one tether cable so that the at least one optical terminal is aerially supported by the at least one tether cable.
 2. The fiber optic network of claim 1, wherein the optical terminal is not aerially supported using a separate support strand.
 3. The fiber optic network of claim 1, wherein the optical terminal is not mounted to a pole.
 4. The fiber optic network of claim 1, the at least one optical terminal further comprising one or more mounting features, wherein the at least one tether cable is attached to the one or more mounting features.
 5. The fiber optic network of claim 4, wherein the at least one tether cable is attached to the one or more mounting features using a cable tie.
 6. The fiber optic network of claim 1, wherein the at least one tether cable forms a portion of a loop before being gripped by the cable clamp.
 7. The fiber optic network of claim 4, wherein the housing comprises a rectangular box form-factor and the one or more mounting features are disposed on a long-side of the rectangular box form-factor.
 8. The fiber optic network of claim 1, wherein the at least one tether cable is terminated with a fiber optic connector.
 9. The fiber optic network of claim 8, wherein the fiber optic connector is optically connected to a distribution cable.
 10. A fiber optic network, comprising: at least one optical terminal, comprising: a housing comprising one or more mounting features; at least one tether cable attached to the housing of the at least one optical terminal, wherein a portion of the at least one tether cable is attached to the one or more mounting features; and a linear array of connection ports disposed on the optical terminal; and a cable clamp for aerially supporting the at least one optical terminal, the cable clamp is attached to a structure and grips a portion of the at least one tether cable so that the at least one optical terminal is aerially supported by the at least one tether cable.
 11. The fiber optic network of claim 10, wherein the optical terminal is not aerially supported using a separate support strand.
 12. The fiber optic network of claim 10, wherein the optical terminal is not mounted to a pole.
 13. The fiber optic network of claim 10, wherein the at least one tether cable is attached to the one or more mounting features using a cable tie.
 14. The fiber optic network of claim 10, wherein the at least one tether cable forms a portion of a loop before being gripped by the cable clamp.
 15. The fiber optic network of claim 10, wherein the housing comprises a rectangular box form-factor and the one or more mounting features are disposed on a long-side of the rectangular box form-factor.
 16. The fiber optic network of claim 10, wherein the at least one tether cable is terminated with a fiber optic connector.
 17. The fiber optic network of claim 16, wherein the fiber optic connector is optically connected to a distribution cable.
 18. A fiber optic network comprising an optical terminal having a cable slack storage arrangement, the optical terminal comprising: a housing comprising a plurality of mounting features disposed on an outer perimeter and a linear array of connection ports, wherein the connection ports are suitable for making an optical connection with the optical terminal and define a connection plane aligned on respective centerlines of the linear array of connection ports, and the plurality of mounting features are at least partially disposed on the connection plane; at least one tether cable attached to the housing of the at least one optical terminal, wherein a portion of the at least one tether cable is wrapped about the outer perimeter of the housing in one or more coils and secured to the housing using one or more of the plurality of mounting features.
 19. The fiber optic network of claim 18, wherein the optical terminal comprises a plurality of actuators associated with the linear array of connection ports.
 20. The fiber optic network of claim 18, further comprising a cable assembly comprising a fiber optic connector and a cable terminated to the fiber optic connector, the fiber optic connector is received in the at least one of the linear array of connection ports.
 21. The fiber optic network of claim 18, wherein the optical terminal further comprises an optical splitter disposed within the housing of the optical terminal.
 22. A method of installing an optical terminal in a fiber optic network, the method comprising: providing an optical terminal comprising a housing and at least one tether cable attached to the housing, wherein the housing comprises at least one mounting feature; attaching a cable clamp to a structure; securing a portion of the at least one tether cable in the cable clamp; and attaching a portion of the at least one tether cable to at least one mounting feature of the housing so that the optical terminal is aerially supported by the at least one tether cable. 